1,721,110 research outputs found
Chorioamnionitis: a risk factor for fetal and neonatal morbidity
No full textDespite widespread use of drugs to arrest preterm labor, there has been no decrease in the numbers of low-birth-weight or preterm infants in the last 20 years. Evidence from many sources links preterm birth to symptomatic and subclinical infections. Recently, an increasing body of evidence has suggested that not only is subclinical infection responsible for preterm birth but also for many serious neonatal sequelae, including periventricular leukomalacia, cerebral palsy, respiratory distress and even bronchopulmonary dysplasia and necrotizing enterocolitis. Proxies of intrauterine infection include clinical chorioamnionitis, histological chorioamnionitis and intraamniotic increase in cytokines, which have been found to be associated with acute neonatal morbidity and mortality and, at least to some degree, with neurological impairment, chronic lung disease and thymus involution in the preterm infant. The infectious/inflammatory mechanisms involved are not fully understood, and the types of microbes and genetic features of host adaptive and innate immune responses need to be better characterized
Oxidant injury in neonatal erythrocytes during the perinatal period
No full textIt has been known for many decades that oxidative stress leads to oxidation of hemoglobin and damage to the erythrocyte membrane. More recently, the factors involved in denaturating of membrane proteins and lipid peroxidation have been investigated in detail, as well as the mechanism of reactive oxygen species formation in red cells. Oxidative stress depletes adenosine triphosphate (ATP) and adenine nucleotides, whereas adenosine monophosphate (AMP) deaminase seems to depress energy metabolism by blocking the salvage pathway of purine nucleotides. Depletion of ATP and activation of AMP deaminase are related to calcium ion concentrations. Denaturating of membrane proteins generally precedes lipid peroxidation and consequent phagocytosis due to caspase activation. Extensive investigations demonstrated the key role of oxidative stress and iron release in a reactive form causing membrane protein damage via the Fenton reaction and hydroxyl radical production. In the absence of efficient protection by antioxidant factors and other molecules such as flavonoids, oxidative stress is responsible for the release of iron in reactive form, predisposing red cells to hemolysis through the formation of senescence antigen. Other well-known sources of oxidative stress in red cells are free radical production outside the red cell by activated phagocytes, endothelial metabolism, hyperoxia, ischemia-reperfusion and the arachidonic acid cascade. CONCLUSION: The recent insight into the mechanism of oxidative injury of red cells and evidence of relationships between erythrocyte oxidative stress and hypoxia suggest that increased hemolysis is induced by severe hypoxia and acidosis in the fetus as well as the newborn
The Timing of Neonatal Brain Damage
No full textAlthough neonatal morbidity and mortality are less than in the past, the risk of pre-natal and neonatal brain damage has not been eliminated. In order to optimize pre-natal, perinatal and neonatal care, it is necessary to detect factors responsible for brain damage and obtain information about their timing. Knowledge of the timing of asphyxia, infections and circulatory abnormalities would enable obstetricians and neonatologists to improve prevention in pre-term and full-term neonates. Cardiotocography has been criticized as being too indirect a sign of fetal condition and as having various technical pitfalls, though its reliability seems to be improved by association with pulse oximetry, fetal blood pH and electrocardiography. Neuroimaging is particularly useful to determine the timing of hypoxic-ischemic brain damage. Cranial ultrasound has been used to determine the type and evolution of brain damage. Magnetic resonance has also been used to detect antenatal, perinatal and neonatal abnormalities and timing on the basis of standardized assessment of brain maturation. Advances in the interpretation of neonatal electroencephalograms have also made this technique useful for determining the timing of brain lesions. Nucleated red blood cell count in cord blood has been recognized as an important indication of the timing of pre-natal hypoxia, and even abnormal lymphocyte and thrombocyte counts may be used to establish pre-natal asphyxia. Cord blood pH and base excess are well-known markers of fetal hypoxia, but are best combined with heart rate and blood pressure. Other markers of fetal and neonatal hypoxia useful for determining the timing of brain damage are assays of lactate and markers of oxidative stress in cord blood and neonatal blood. Cytokines in blood and amniotic fluid may indicate chorioamnionitis or post-natal infections. The determination of activin and protein S100 has also been proposed. Obstetricians and neonatologists can therefore now rely on various methods for monitoring the risk of brain damage in the antenatal and post-natal periods
New biomarkers of fetal-neonatal hypoxic stress
No full textThe complex pathophysiological mechanisms underlying perinatal hypoxia make it difficult to define early markers of severe hypoxia-ischemia encephalopathy. However, as progress in the development of neuroprotective therapeutic measures continues, the early identification of neonates at risk of severe hypoxic-ischemic encephalopathy is an important goal for appropriate decision making. Although the timing of perinatal hypoxic brain damage may vary and is sometimes unknown, high levels of non-protein-bound iron and high nucleated red blood cell counts in cord blood indicate an antepartum origin of neurological impairment, because they can occur only as a consequence of a pre-existing asphyxic event. CONCLUSION: The combined assessment of nucleated red blood cells and non-protein-bound iron at birth seems extremely useful for the early identification of newborns at high risk of brain damage. Activin A also seems to be a reliable marker of perinatal hypoxia. Prospective long-term follow-up studies are needed to verify their predictive role
Red blood cell involvement in fetal/neonatal hypoxia
No full textFree radical release plays an important role in the development of brain injury following hypoxic-ischemic encephalopathy. It causes endothelial cell damage and anomalies in NMDA receptors, synaptosome structure and astrocyte function. Mitochondrial dysfunctions caused by asphyxia, reperfusion after ischemia, arachidonic acid cascade, catecholamine metabolism and phagocyte activation are known sources of reactive oxygen species, particularly the superoxide anion (O2(-)). O2(-) mainly induces peroxidation by the Fenton/Haber Weiss reaction or via iron-oxygen complexes. Since both reactions require reactive heavy metals, non-protein-bound iron (NPBI) is essential for the induction of lipid peroxidation. Experimental studies have demonstrated the neurotoxicity of iron in ischemia-reperfusion. Normal axonal transport of brain iron is also reported to be disrupted in hypoxia-ischemia, leading to a buildup of iron in the white matter. The free iron content of erythrocytes (ICRBC) is considered a marker of oxidative stress. Free iron release is accompanied by the oxidation of membrane proteins and the appearance of senescent antigen, as measured by autologous IgG binding. Our preliminary results suggest a significant positive correlation between plasma free iron and the number of nucleated red cells in cord blood, currently considered a reliable index of lasting intrauterine asphyxia but also possessing a high predictive value for poor neurodevelopmental outcome. The rate of erythropoiesis and the entity of ICRBC are related to the degree of asphyxia and the probability of neurological impairment. Since even an increase in NPBI during asphyxia is related to a poor outcome, iron released by red cells could possibly also contribute to NPBI levels
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